Magnetic current concentrator connector for electric motor

ABSTRACT

A connector for an electric motor including a magnetic ring which is the seat of a magnetic field tied to operating parameters of the motor. A magnetic flux conduction member forms a flux concentrator interposed, when a connector is fixed on the motor, between the magnetic ring and a Hall-effect sensor to measure the magnetic flux conducted by the magnetic flux conduction member. The electric motor can be used with geared motors for window-lifting systems, seat actuation systems or sunroof systems, in the automobile field.

BACKGROUND OF THE INVENTION

The present invention relates to the field of electric motors, inparticular geared motors for automobile accessories, which are used forexample in window-lifting systems, seat actuation systems or sunroofsystems.

The invention is more precisely aimed at a connector for an electricmotor, said motor comprising a magnetic ring which is the seat of amagnetic field tied to operating parameters of the motor.

The motors or geared motors to which the invention applies areassociated with a control system which uses motor speed and/or positionparameters. These parameters are fed to the control system by aHall-effect sensor associated with the magnetic ring, which is adaptedso as to deliver to the sensor a magnetic field dependent on the speedand/or position of the motor shaft.

Generally, the electronic control devices of such motors or gearedmotors comprise a circuit board secured to the casing of the motor, saidboard comprising motor electrical supply connections and the Hall-effectsensor. This sensor is fixed on a board part formed of a rigid stripthat penetrates into the casing of the motor up to a region neighboringthe magnetic ring, in such a way that the sensor is located in thevicinity of said ring.

It can readily be seen that the presence of such an electronic controlmodule on the casing of the motor is incompatible with a high degree ofstandardization of motors, since such a configuration of the motor andof its casing is not suited to an application in which the speed and/orposition sensor is dispensed with, and in which the electronic controldevice of the motor is located remotely some distance away from themotor.

SUMMARY OF THE INVENTION

A main aim of the invention is to remedy this drawback, and to propose aconnector for an electric motor, which makes it possible to transportinformation of magnetic type to an electronic processing device and iscapable of amalgamating with this function the conventional functionsfor the electrical supply of the motor.

With this aim, a connector according to the invention comprises at leastone magnetic flux conduction member forming a flux concentratorinterposed, when the connector is fixed on the motor, between themagnetic ring and a Hall-effect sensor adapted so as to measure themagnetic flux conducted by the magnetic flux conduction member.

According to one embodiment, the magnetic flux conduction memberexhibits an elongate part, an end of the elongate part exhibiting asmaller section than the mean section of the elongate part, neighboringthe Hall-effect sensor.

According to a further embodiment, the section of said end decreasesprogressively in the neighborhood of the Hall-effect sensor.

According to a further embodiment, the elongate part of the magneticflux conduction member is made of soft steel.

According to other characteristics of the invention:

-   -   the magnetic flux conduction member comprises at least one metal        pin adapted so that a part of said pin, when the connector is        fixed on the motor, lies in the vicinity of the magnetic ring;    -   the magnetic flux conduction member comprises two metal pins        whose free ends are disposed symmetrically with respect to an        axial plane (P) of the magnetic ring;    -   the connector furthermore comprises at least two electrical        power contacts linked to a supply source for the motor;    -   the electrical contacts comprise a part made of brass;    -   at least one of said electrical power contacts is disposed so as        to constitute a part of the magnetic flux conduction member;    -   said power contact constituting a part of the magnetic flux        conduction member is connected, when the connector is fixed on        the motor, to a metal pad secured to the motor and a part of        which lies in the vicinity of the magnetic ring;    -   said power contact constituting a part of the magnetic flux        conduction member is made of steel;    -   the magnetic flux conduction member is secured to the power        contact;    -   the magnetic flux conduction member is affixed to the power        contact;    -   the connector is secured to a printed circuit on which the        Hall-effect sensor is disposed;    -   the connector is adapted so as to be fixed in a detachable        manner on the electric motor.

The invention is also aimed at a geared motor for automobileaccessories, such as a window or a seat, comprising a rotor shaftequipped with a magnetic ring, characterized in that it comprises aconnector as described above.

BRIEF DESCRIPTION OF THE DRAWINGS

Exemplary embodiments of the invention will now be described with regardto the appended drawings, in which:

FIG. 1 is an end-on view in partial section of a geared motor equippedwith a connector according to a first embodiment of the invention;

FIG. 2 is a diagrammatic cross section along the line 2—2 of FIG. 1representing the magnetic flux conduction member and the magnetic ring;

FIG. 3 is a view similar to FIG. 1 according to a second embodiment ofthe invention;

FIG. 4 is a cross section similar to FIG. 2, along the line 4—4 of FIG.3;

FIG. 5 is a partial sectional end-on view of a third embodiment of theinvention;

FIG. 6 is a sectional diagrammatic side view of the embodiment of FIG.5.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Represented in FIG. 1 is a geared motor 1 including a motor 2 and areduction gear 3, the motor 2 being equipped with an electronic controldevice 4 which includes a printed circuit board 5.

The motor 2 includes a stator 6 forming a shroud in which permanentmagnets (not represented) are housed and supporting by way of a bearing7 an end 8A of a rotor shaft 8 of a rotor 9. In a known manner, thelatter includes windings coiled around stacked laminations. A commutator10 is linked electrically to the rotor 9 and receives by way of brushes11 the motor supply current transmitted to the motor 2 at the level ofsupply lugs 12.

The geared motor 1 further includes a casing 20 rigidly fixed to thestator 6 and supporting by way of a second bearing assembly, notrepresented, a second end of the rotor shaft 8. The rotor shaft 8 spansituated on the same side as the second shaft end is configured as athreaded rod forming a worm screw, which drives a set of gears of thereduction gear 3. A magnetic ring 21 is fixed on the rotor shaft 8 in aregion neighboring the supply lugs 12.

The casing 20 exhibits an aperture 22 near the supply lugs 12 thatreceives in a detachable manner an electrical connector 30 into whichthe printed circuit board 5 of the electronic control device 4 is fixed.The printed circuit board 5 supports an electronic circuit able todeliver a supply current for the motor 2. The connector 30 is held inposition by a releasable fastener of conventional type (notillustrated). The current delivered by the electronic circuit travelsthrough power tags 31 secured to the printed circuit board 5, each ofthe power tags 31 being connected fixedly to an end 32A of a contact 32of a “stirrup” type, that is one end of the power contact 32 includes anelastic clip having two inwardly arched symmetric contact portions.

The printed circuit board 5 additionally supports a Hall-effect sensor33 intended to receive a magnetic flux indicative of the speed and/orposition of the rotor shaft 8 and to transmit to the electronic controldevice 4 an electrical signal indicative of these operating parametersof the motor 2.

The connector 30 also includes a magnetic flux conduction memberincluding, in the embodiment of the invention represented in FIG. 1, oftwo parallel metal pins 35, one end of which is fixed to the printedcircuit board 5 in the vicinity of the Hall-effect sensor 33. The otherend 35A constituting the free end of the pin 35 is situated, when theconnector 30 is inserted into the aperture 22 of the correspondingcasing 20 and held by the fastener, near a periphery of the magneticring 21. The two free ends 35A are preferably disposed symmetricallywith respect to an axial plane P of the magnetic ring 21.

The relative position of the metal pins 35 and of the magnetic ring 21is more clearly apparent in FIG. 2. The magnetic ring 21 generates amagnetic field of constant strength whose direction varies with theangular position of the rotor shaft 8, and therefore the magnetic fluxconducted by the pins 35 of the magnetic ring 21 to the Hall-effectsensor 33 is dependent on an angular position of the rotor shaft 8. Theelectrical signal delivered by the Hall-effect sensor 33 thereforeaffords access to the speed and/or angular position of the rotor shaft8. Preferably, the pins 35 forming magnetic flux conduction members aremade of steel.

Represented in FIG. 3 is a geared motor 101 of the same type as above,whose motor 102 includes a rotor shaft 108 on which a magnetic ring 121is fixedly mounted. A connector 130 includes a printed circuit board 105forming part of an electronic control device 104 of the electric motor102 and supporting a pair of supply tags 131 situated in proximity to aHall-effect sensor 133. The connector 130 is fixed in a detachablemanner to the casing 120 of the geared motor 101 by conventionalreleasable fastener (not represented). The connector 130 includescontacts 132 of “stirrup” type, fixed by one of their ends 132A to thesupply tags 131 and intended to be connected by a second end 132B tomotor supply lugs 112.

In this embodiment of the invention, and as will be more clearly seen inFIG. 4, the two lugs 112 each exhibit a part 140 overlapping themagnetic ring 121 oblique with respect to the direction of coupling ofthe contacts 132, and which lies in the vicinity of the magnetic ring121 in an almost tangential manner. The two parts 140 are preferablysymmetric with respect to the axial plane P of the magnetic ring 121.Likewise, the supply tags 131 include a part 131A partially overlappingthe Hall-effect sensor 133, so that the lugs 112, the contacts 132 andthe supply tags 131 fulfil the flux concentrator function and constitutea member for conducting the magnetic flux of the magnetic ring 121 tothe Hall-effect sensor 133.

Preferably, the contacts 132 are made of steel, a material of this typeoffering an acceptable compromise between the qualities of electricaland magnetic conduction, and exhibiting excellent mechanical properties.

It is readily understood that the two embodiments of the invention whichhave just been described make it possible to design geared motors with ahigh degree of standardization. Specifically, it is not necessary tosecure a printed circuit board carrying a Hall-effect sensor to themotor in order to achieve the position and/or speed sensor functions,and hence to modify the casing of a standard motor. Thus, one and thesame motor can be used regardless of the application of the gearedmotor, and regardless of the type of sensor required (speed/position),only the connector having to be modified.

FIGS. 5 and 6 represent a geared motor according to a third embodimentof the invention. A connector 230, represented only partially, includes,as in the other embodiments, a printed circuit board 205 that supports aHall-effect sensor 233.

Magnetic flux conduction pins 241 each exhibit an end near a Hall-effectsensor part 233A and 233B, respectively. The other end of the pins 241can, for example, come into contact with a respective lug 212. As in theembodiment of FIG. 3, the lugs 212 supplies the magnetic ring 221mounted on a rotor 209. The magnetic flux of the magnetic ring 221 canthus be conducted from the magnetic ring 221 up to the Hall-effectsensor 233.

As represented in FIG. 6, the magnetic flux conduction pins 241 exhibitan elongate part. This elongate part exhibits an end neighboring thesensor 233 of reduced section, that is to say of smaller section thanthe mean section of the elongate part. This reduced section can forexample be obtained by using flat pins of reduced width at the level ofthis end. The reduced section makes it possible to concentrate themagnetic flux at the level of the Hall-effect sensor 233. The amplitudeof the magnetic flux conducted by the pins 241 up to the Hall-effectsensor 233 is thus increased. Similar pins of reduced section may ofcourse be used in the previous embodiments of the invention.

Pins whose section decreases progressively toward the Hall-effect probeare preferably used. The flux losses in proximity to the Hall-effectprobe are thus reduced. The pins 241 are preferably made of soft iron,steel, nickel or ferrite. A material exhibiting high magneticpermeability is generally used.

According to a variant, supply tags 242 electrically link an electricalsupply harness 208 to the lugs 212. The supply tags 242 are preferablymade of copper or brass so as to ensure high conduction of the electriccurrent between the supply harness 208 and the lugs 212.

The supply tags 242 and the pins 241 can be fixed at the same level asthe lugs 212. Each supply tag 242 can also be fitted to a pin, forexample by soldering, by adhesive bonding or by riveting. It is alsopossible to use other means of mechanical fixing or simply to stack atag on top of a pin, retaining them by their respective ends.

The invention, which makes it possible to conduct magnetic informationto a remote sensor, renders a single geared motor configurationadaptable to various applications, the standardization of the gearedmotor being offset by the diversification of the connection engineering,thereby achieving a considerable saving with regard to the completesystem.

1. A motor for an automobile accessory, the motor comprising: a rotorshaft having a magnetic ring; a lug having a part near the magneticring, wherein the lug is secured to the motor; and a connectorincluding: a magnetic flux conduction member forming a flux concentratorwhen the connector is fixed on the motor between the magnetic ring and asensor, said sensor measuring a magnetic flux conducted by the magneticflux conduction member, the magnetic flux conduction member including atleast one longitudinal member neighboring the sensors, and at least twoelectrical contacts linked to a supply source for the motor, wherein atleast one of the at least two electrical contacts is disposed so as toconstitute a part of the magnetic flux conduction member, wherein thelug and the connector are separate components that are connected whenthe connector is fixed to the motor.
 2. The motor of claim 1, whereinthe at least one longitudinal member is made of steel.
 3. The motor ofclaim 1, wherein the magnetic flux conduction member is secured to atleast one of the at least two electrical contacts.
 4. The motor of claim1, wherein the at least two electrical contacts comprise a part made ofbrass.
 5. The motor of claim 1, wherein the at least two electricalcontacts are made of steel.
 6. The motor of claim 1, wherein theconnector and the sensor are both disposed on a printed circuit board.7. The motor of claim 1, wherein the sensor is a Hall-effect sensor. 8.The motor of claim 1, wherein a cross-section of the at least onelongitudinal member decreases progressively near the sensor.
 9. Themotor of claim 1, wherein said lug comprises two metal pins each havinga free end that is disposed symmetrically with respect to an axial planeof the magnetic ring, wherein a portion of each of the two metal pins isnear the magnetic ring when the connector is fixed on the motor.
 10. Themotor of claim 1, wherein the connector is detachably fixed to themotor.